A cover plate for maintaining axial alignment between a blade assembly and a rotor disk and transferring centrifugal loading directly to the rotor disk. The cover plate comprises a plate key extending axially from an elongate member, the plate key configured to engage a keyway of the rotor disk assembly and/or a notch of the blade key.
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7. A cover plate for maintaining axial alignment between a blade assembly and a rotor disk comprising:
a plurality of flat arcuate segments, each segment having an outer portion and inner portion with respect to a radial direction, and a forward surface normal to an axial direction defined by the arcuate segment; and
a key extending in the axial direction from the forward surface, the key configured to be received within a fir tree keyway defined in the rotor disk for retaining the blade assembly at an axial notch of a fir tree blade key that is also received within the fir tree keyway, wherein the plate key comprises a shape including a plurality of axially extending, circumferentially oriented plate key ridges, the shape being complimentary to a portion of the fir tree keyway of the rotor disk corresponding to the axial notch in the fir tree blade key, wherein the plate key ridges are configured to axially align with axially extending, circumferentially oriented blade key ridges and engage with corresponding axially extending recesses of the fir tree keyway, and wherein the plate key is configured to extend less than a full radial length of the fir tree keyway.
1. A rotor assembly comprising:
a rotor disk concentric with an axis of rotation having a plurality of axially-extending keyways arranged around the outer circumference of the disk, wherein each of the axially-extending fir tree keyways defines a plurality of axially extending recesses;
a plurality of blade assemblies, each of the plurality of blade assemblies comprising a blade, a blade skirt, and a fir tree blade key; the blade skirt positioned between the blade and the fir tree blade key; each fir tree blade key having a shape including a plurality of axially extending, circumferentially oriented blade key ridges, the shape being complimentary to a respective fir tree keyway of the plurality of fir tree keyways of the rotor disk and received in the respective fir tree keyway such that each of the respective blade assemblies of the plurality of blade assemblies are restrained from relative movement in the radial and circumferential directions, wherein each fir tree blade key defines an axial notch extending a full circumferential width of the fir tree blade key and part of a radial height of the fir tree blade key; and,
a plurality of cover plate segments; each of the plurality of cover plate segments forming a respective portion of an annular cover plate ring concentric with the axis of rotation, each of the plurality of cover plate segments having a front plate face and a back plate face each normal to the axis and having a thickness in the axial direction less than the radial width of each segment, the front and back plate face having a radially outer portion, radially inner portion, and a plate key extending from the front plate face of the cover plate segment that is received in a portion of the respective fir tree keyway at the axial notch of the respective fir tree blade key, wherein the plate key comprises a shape including a plurality of axially extending, circumferentially oriented plate key ridges, the shape being complimentary to a portion of a respective fir tree keyway of the plurality of fir tree keyways of the rotor disk corresponding to the axial notch in the respective fir tree blade key, wherein the plate key ridges axially align with the axially extending, circumferentially oriented blade key ridges and engage with corresponding axially extending recesses of the respective fir tree keyway, and wherein the plate key extends less than a full radial length of the respective fir tree keyway;
wherein, each front plate face of the plurality of cover plate segments engage one or more of the respective blade keys and the radially outer portions engage a blade groove defined by the blade skirt and the radially inner portions engage a disk groove in the disk restricting relative axial movement of the blade assembly with respect to the rotor disk; and the plate key engages the portion of the fir tree keyway restricting radial movement of the cover plate segment.
2. The rotor assembly of
3. The rotor assembly of
4. The rotor assembly of
6. The rotor assembly of
8. The cover plate of
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The present disclosure relates generally to turbine machines, and more specifically to a cover plate assembly for a gas turbine engine rotor assembly.
Gas turbine engines typically include at least a compressor section, a combustor section, and a turbine section. In general, during operation, air is pressurized in the compressor section and is mixed with fuel and burned in the combustor section to generate hot combustion gases. The hot combustion gases flow through the turbine section, which extracts energy from the hot combustion gases to power the compressor section and other gas turbine engine loads.
The compressor section and the turbine section may each include alternating rows of rotor and stator assemblies. The rotor assemblies carry rotating blades that create or extract energy (in the form of pressure) from the core airflow that is communicated through the gas turbine engine. The stator assemblies include stationary structures called stators or vanes that direct the core airflow to the blades to either add or extract energy.
Rotor assemblies typically include rotor disks that extend between disk rims and disk bores. Blades are mounted near the rim of a rotor disk. Cover plates may be used to seal the connection between the blades and the rotor disks that carry the blades, and to prevent axial movement of the blades relative to the rotor disks.
The following will be apparent from elements of the figures, which are provided for illustrative purposes and are not necessarily to scale.
While the present disclosure is susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail herein. It should be understood, however, that the present disclosure is not intended to be limited to the particular forms disclosed. Rather, the present disclosure is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the disclosure as defined by the appended claims.
For the purposes of promoting an understanding of the principles of the disclosure, reference will now be made to a number of illustrative embodiments illustrated in the drawings and specific language will be used to describe the same.
A rotor assembly 100 is illustrated in
Rotor assembly 100 comprises a rotor disk 104, a blade assembly 120, and a rotor assembly cover plate 140. In some embodiments rotor assembly 100 further comprises a forward sealing plate 106. Rotor assembly 100 may further comprise a stator assembly (not shown) positioned radially forward and/or radially aft of the rotor assembly 100. A pairing of a rotor assembly 100 with a stator assembly is called a stage, and the compressor section and turbine section of a turbine engine typically comprise multiple stages.
Rotor disk 104 extends radially outward from a disk bore 108 to a disk rim 110. The disk rim 110 is the most radially outward portion of the rotor disk 104. In the vicinity of the disk rim 110, rotor disk 104 may define one or more keyways (not visible in
Rotor disk 104 may include mechanisms for sealing in an axially forward or aft direction. For example, the rotor disk 104 illustrated in
Blade assembly 120 comprises a blade 122, blade skirt 124, and blade key (not shown in
Rotor assembly 100 typically comprises a plurality of blade assemblies 120 spaced about the circumference of the rotor disk 104, with each blade assembly 120 coupled to the rotor disk 104 by a respective blade key and disk keyway. With the disk keyway disposed in the blade key, radial movement of the rotor disk 104 is restricted.
Cover plate 140 is disposed between rotor disk 104 and blade assembly 120, and is configured to reduce, restrain, or prevent axial movement of blade assembly 120 relative to rotor disk 104. In the rotor assembly illustrated in
The cover plate 140 and rotor assembly 100 illustrated in
Thus it is desirable to provide a loading pathway whereby the cover plate 140 transfers load directly to the blade disk 104 rather than transferring load to the blade disk 104 via the blade assembly 120. Such a modification to the rotor assembly 100 depicted in
The present disclosure is thus directed to rotor assembly cover plates, rotor assemblies, systems, and methods of transferring load directly from a cover plate to a rotor disk and avoiding the transfer of load from a cover plate to a blade assembly. More specifically, the present disclosure is directed to rotor assembly cover plates having one or more plate keys configured to engage the keyway of a rotor disk, thus directly transferring the centrifugal force loading of the cover plate to the rotor disk in lieu of the blade assembly.
Cover plate 240 comprises an elongate member 241 extending in a generally axial direction between a forward plate face 242 and an aft plate face 243, and in a generally radial direction between a radially inner edge 244 and a radially outer edge 245. A radially inner portion 246 proximate the radially inner edge 244 and a radially outer portion 247 proximate the radially outer edge 245 may include tapered or chamfered surfaces. A central portion 248 extends between radially inner portion 246 and radially outer portion 247. Forward plate face 242 may be referred to as a front plate face and aft plate face 243 may be referred to as a back plate face.
A thickness T of the cover plate 240 is defined as the dimension between the forward plate face 242 and aft plate face 243. In some embodiments, one or both of the radially inner portion 246 and radially outer portion 247 may have a thickness T that is different from the thickness T of central portion 248. In some embodiments, one or both of the radially inner portion 246 and radially outer portion 247 may have a thickness T that is greater than the thickness T of central portion 248.
A radial width W of cover plate 240 is defined as the dimension between the radially inner edge 244 and radially outer edge 245.
A plate key 250 extends axially forward from the forward plate face 242. In some embodiments the plate key 250 may be normal or substantially normal to the forward plate face 242. Plate key 250 comprises a forward key face 251 and a plurality of exterior surfaces 252. Exterior surfaces 252 may form an axially-extending ridge 253, or tooth, that may be configured to engage the keyway of rotor disk 104, or to match or substantially match the profile of the blade key. Plate key 250 may present, at a cross-section normal to the axis of rotation, a shape such as a trapezoid, rhombus, or polygon, to name merely a few non-limiting examples. One or more of exterior surfaces 252 may be tapered towards or chamfered to the forward key face 251.
The plate key 250 may be sized and shaped to compliment the blade key, which is pictured in
The plate key 250 may be dimensioned to substantially match the cross-section of the radially innermost ridge 227 of the blade key 226 when viewed in cross-section normal to the axis of rotation. Similarly, the plate key 250 may be dimensioned such that the exterior surfaces of the plate key 250 axially align with the exterior surfaces of one or more ridges 227 of the blade key 226.
When installed in the keyway of a rotor disk, the ridges 227 of blade key 226 radially retain the blade assembly 220 during rotation of the rotor assembly. In other words, under the influence of centrifugal forces from rotation of the rotor assembly, the blade assembly 220 does not move radially outward and separate from the rotor assembly because of blade key 226 engagement with a keyway of the rotor disk. Similarly, the engagement of exterior surfaces 252 of the plate key 250 radially retains the cover plate 240 during rotation of the rotor assembly. Centrifugal force loading is transferred to the rotor disk via the plate key 250 and rotor disk keyway.
As shown in
In some embodiments such as those illustrated in
In an alternative embodiment, a cover plate may be configured to transfer load to the blade key instead of to the blade skirt. The load is then transferred from the blade key to the rotor disk. In such an embodiment, load is not transferred directly from the cover plate to the rotor disk, but improvements are still realized because loading is not transferred to the blade groove and thus reinforcement of the blade skirt is not required. Such an alternative embodiment is presented in
As shown in
In the embodiment disclosed in
The present disclosure further provides methods for both axially retaining a blade assembly relative to a rotor disk and reducing or eliminating the centrifugal loading of the blade assembly and/or blade skirt. A method may comprise providing a cover plate having a plate key configured to engage a keyway of a rotor disk and/or the blade key of a blade assembly. The method may further comprise rotating a rotor disk having a disk keyway engaged by a plate key of a cover plate, wherein during rotation of the rotor disk and cover plate the centrifugal load of the cover plate is transferred from the cover plate to the rotor disk via the plate key—keyway engagement.
The present disclosure further provides methods of assembling a rotor assembly. In some embodiments, a method comprises engaging a cover plate having a plate key with the keyway of a rotor disk, and then engaging the blade key of a blade assembly with the keyway of the rotor disk. The cover plate may reduce or prevent axial movement of the blade assembly, and the centrifugal load of the cover plate may be transferred from the cover plate to the rotor disk via the plate key—keyway engagement.
The present disclosure provides numerous advantages over prior art rotor assemblies and rotor assembly cover plates. Most significantly, the cover plate segments disclosed herein allow for centrifugal force loading of the cover plate segment to be transferred directly to the rotor disk rather than first transferred to the blade assembly. By reducing or eliminating the loading of the blade assembly by the cover plate segment, the blade assembly may require less reinforcement and may therefore be lighter. Weight reduction of rotor assemblies carries substantial advantage, particularly in the field of aviation engines. Additionally, reducing or eliminating the loading of the blade assembly by the cover plate segment likewise reduces the stresses incurred at the blade groove, thus reducing the rate of premature failure of the blade assemblies and/or increasing the service life of such an assembly. In some embodiments the mass of the cover plate may be reduced as a result of the improved load paths.
According to aspects of the present disclosure, a rotor assembly may comprise a rotor disk concentric with an axis of rotation having a plurality of axially-extending keyways arranged around the outer circumference of the disk, a plurality of blade assemblies, and a plurality of cover plate segments. Each of the plurality of blade assemblies comprises a blade, a blade skirt, and a blade key. The blade skirt is positioned between the blade and the key, the key having a shape being complimentary to the keyway of the disk and received in the keyway such that the blade assembly is restrained from relative movement in the radial and circumferential directions. Each of the plurality of cover plate segments form a respective portion of an annular cover plate ring concentric with the axis of rotation, each of the plurality of cover plate segments having a front plate face and a back plate face each normal to the axis and having a thickness in the axial direction less than the radial width of each segment. The front and back plate face have a radially outer portion, radially inner portion, and a plate key extending from the front plate face of the cover plate segment that is received in a portion of the keyway. Each front plate face of the plurality of cover plate segments engage one or more blade keys and the radially outer portions engage a blade groove defined by the blade skirt and the radially inner edges engage a disk groove in the disk restricting relative axial movement of the blade assembly with respect to the disk. The plate key engages the portion of the keyway or the blade key restricting radial movement of the cover plate segment.
In some embodiments the keyway comprises a plurality of axially-extending recesses and the blade key has a corresponding plurality of complimentary axially-extending ridges. In some embodiments the plate key has at least one axially extending ridge corresponding to one or more of the plurality of axially-extending recesses of the keyway. In some embodiments the plate key has a plurality of axially extending ridges corresponding to the plurality of axially-extending recesses of the keyway.
In some embodiments the blade key comprises a radially inner portion with a axial length less than the axial extent of the keyway. In some embodiments the plate key has an axial length less than or equal to the axial extent of the keyway. In some embodiments the plate key engages the keyway. In some embodiments the plate key engages the blade key. In some embodiments the number of the plurality of cover plate segments is equal to the number of the plurality of keyways.
According to another aspect of the present disclosure, a cover plate for maintaining axial alignment between a blade assembly and a rotor disk comprises a plurality of substantially flat arcurate segments, each segment having an outer portion and inner portion with respect to the radial direction; a forward surface substantially normal to an axial direction defined by the arcurate segment; and a key extending in the axial direction from the forward surface, the key configured to be received within a keyway defined in the rotor disk.
In some embodiments the key comprises a plurality of teeth complimentary to recesses in the keyway. In some embodiments the key has an axial width less than the axial width of the keyway proximate the key. In some embodiments each of the segments have a plurality of keys.
According to still further aspects of the present disclosure, a blade assembly for attachment to a rotor disk comprises a blade attached to a blade skirt; a key extending downward from the blade skirt and comprising a plurality of horizontally oriented ridges extending lengthwise from the front to the rear on oppositely disposed sides and a notch formed in a back portion of the key; and, a skirt, wherein the skirt comprises an upper surface substantially perpendicular to the blade and defining a boundary of a fluid passage, and a downward opening slot formed in an aft portion of the skirt.
In some embodiments the notch begins on the bottom of the key and extends partially up the key. In some embodiments the notch has a rectangular cross section viewed normal to the axis of rotation. In some embodiments the notch begins above the bottom of the key and extends partially up the key. In some embodiments a surface defining the radially outward portion of the notch is slanted. In some embodiments the notch extends from one oppositely disposed, side to the other. In some embodiments the notch is buried within the oppositely disposed sides.
The present application discloses one or more of the features recited in the appended claims and/or the following features which, alone or in any combination, may comprise patentable subject matter.
Although examples are illustrated and described herein, embodiments are nevertheless not limited to the details shown, since various modifications and structural changes may be made therein by those of ordinary skill within the scope and range of equivalents of the claims.
Whitten, Michael R., Snyder, Brandon, Sellhorn, James
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Apr 25 2017 | SNYDER, BRANDON | Rolls-Royce Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 042214 | /0812 | |
May 01 2017 | SELLHORN, JAMES | Rolls-Royce Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 042214 | /0812 | |
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